KR100490128B1 - Deflector - Google Patents

Abstract

The pin-shaped or barrel-shaped distortion in the horizontal direction of the scanning line generated at the upper and lower portions of the cathode ray tube screen is corrected and adjusted.

For example, the sawtooth wave signal of the vertical period is supplied to the amplifier 1 for controlling the amplitude and polarity provided in series and the amplifier 2 for controlling the DC level. The signal from this amplifier 2 is supplied to the amplifier 3 for voltage and current conversion. Again, the current signal from this amplifier 3 is supplied to one end of the series circuit of the pair of coils 5a and 5b provided by sandwiching the neck portion of the cathode ray tube 4. The other end of the series circuit is also grounded. By flowing a modulated current in the form of a sawtooth at a vertical period in the coils 5a and 5b and changing its amplitude or polarity, the scanning lines can be distorted in the barrel or pin shape in the upper and lower parts of the screen, and occur in the original. The distortion can be corrected.

Description

Deflector

The present invention relates to a deflection apparatus which is most suitable for use in a water receiver using, for example, a color cathode ray tube.

For example, in a color cathode ray tube, three electron beams emitted from an electron gun are focused on a deflection center through a predetermined trajectory, and the deflection center uses a horizontal sawtooth wave and a vertical sawtooth wave in front of the screen. The image is displayed by being deflected over the image.

However, when such a deflection scan is performed using a sawtooth wave of a simple horizontal and vertical period, for example, so-called pin or barrel distortion occurs in the vertical direction. Therefore, conventionally, in order to correct such a vertical distortion, for example, the distortion of these images has been corrected by modulating the horizontal deflection current in a vertical period or the like.

By the way, in the case of performing the deflection scan as described above, even in the upper and lower portions of the screen of the cathode ray tube, a horizontal pin-shaped or barrel-shaped distortion occurs in the scanning line. Therefore, correction is also performed to eliminate the distortion of these images in such horizontal distortion (called N / S pin distortion).

However, in the case where the correction of the distortion in the horizontal direction is performed electrically, for example, the vertical deflection current is modulated in the horizontal period. For this reason, it is difficult to realize the frequency characteristic in general modulation circuits. Therefore, conventionally, for example, modulation using a resonant circuit is performed, but the frequency to which the resonant circuit is applied is limited, and a complex configuration such as switching of the resonant frequency is required to be applied to a plurality of frequencies.

In addition, a method of correcting by attaching a permanent magnet to a deflection yoke is known, but in such a method, the amount of correction cannot be changed according to individual cases, for example, the adjustment of the characteristics of each device cannot be adjusted. will be. In addition, it is not possible to adjust the correction amount according to the user's preference or the like.

The present application has been made in view of such a point, and the problem to be solved is that there was no means for correcting this well for the horizontal pin-shaped or barrel-shaped distortion of the scanning line occurring at the upper and lower portions of the screen of the cathode ray tube. will be.

Therefore, in the present invention, a pair of coils are provided in the neck portion of the cathode ray tube, and the coil generates a magnetic field crossing the neck portion, thereby moving the trajectory of the electron beam incident on the deflection center up and down. The horizontal pin-shaped or barrel-shaped distortion of the scanning line generated at the upper and lower portions of the tube screen can be corrected and adjusted well.

In other words, in the present invention, a pair of coils are provided in the neck portion of the cathode ray tube, and the coil generates a magnetic field crossing the neck portion to move the trajectory of the electron beam incident on the deflection center up and down, This is achieved by correcting the distortion. EMBODIMENT OF THE INVENTION Hereinafter, although this invention is demonstrated with reference to drawings, FIG. 1 is a block diagram which shows the structure of an example of the deflection apparatus applied by this invention.

1, for example, a vertical deflection current from the vertical deflection current output circuit 11 is supplied to one end of the vertical deflection yoke 12. In FIG. The other end of the vertical deflection yoke 12 is grounded through a resistor 13 for current detection. As a result, in the vertical deflection yoke 12, the vertical deflection of the electron beam from the deflection center described above is performed, and at the one end of the current detection resistor 13, the sawtooth wave signal of the vertical period is taken out.

Thus, the sawtooth wave signal is supplied to the amplifier 1 for controlling the amplitude and polarity provided in series and the amplifier 2 for controlling the DC level. The signal from this amplifier 2 is supplied to the amplifier 3 for voltage and current conversion. Again, the current signal from the amplifier 3 is supplied to one end of a series circuit of the pair of coils 5a and 5b provided by sandwiching the neck portion of the cathode ray tube 4. The other end of the series circuit is also grounded.

2 shows the structure of the neck part of the cathode ray tube 4 and the pair of coils 5a and 5b. In Fig. 2, for example, E-shaped cores 6a and 6b are provided on both outer sides of the neck portion of the cathode ray tube 4 at the point where three electron beams from an electron gun (not shown) intersect. The coils 5a and 5b are provided in the center leg portions, respectively. Further, for example, the beams 7a to 7d for beam shape correction are provided in the leg portions on both sides.

In this apparatus, when a current flows through the pair of coils 5a and 5b, for example, a magnetic field is generated that crosses the neck portion of the cathode ray tube 4 as indicated by an arrow in the figure. For this reason, a force is applied to the electron beam 8 through the center of the magnetic field in the vertical direction by the direction of the magnetic field. For example, the trajectory of the electron beam 8 moves up and down like an arrow.

On the other hand, in the color cathode ray tube described above, for example, when the trajectory of the electron beam is staggered upward, for example, distortion occurs in the scan line as shown in Fig. 3A. In the case where the trajectory of the electron beam is staggered downward, for example, as shown in FIG. 3B, distortion occurs in the scan line. In addition, such a scan line distortion does not occur due to a change in raster position or a change in size due to the vertical deflection magnetic field.

So, for example, after staggering the trajectories of the above-described electron beams up, and moving the raster down by the vertical deflection magnetic field by the minute moved upward by the change of the trajectory, the position of the raster displayed on the screen is not changed. The scanning line can be distorted into a barrel shape at the top of the screen and a pin shape at the bottom of the screen. In addition, in the case where the trajectory of the electron beam is staggered downward, a reverse distortion occurs as described above.

Thus, for example, using the sawtooth wave of the vertical period as described above, for example, to the right of the screen to generate a magnetic field of the right direction, and to the left of the screen of the pair of coils (5a, 5b) Supply the current. As a result, the upward barrel-shaped distortion occurs when the trajectory of the electron beam is staggered upward in the upper part of the screen, and the downward barrel-shaped distortion occurs when the trajectory of the electron beam is staggered downward in the lower part of the screen.

That is, for example, using the above-described sawtooth wave of the vertical period, as shown in FIG. 4A, for example, the orbits of the electron beam are staggered upward at the top of the screen, and staggered downward at the bottom, and by a vertical deflection magnetic field. Reduce raster size. As a result, for example, as shown in Fig. 4B, the upper and lower portions of the screen can be distorted in a barrel shape. In addition, when the polarity of the sawtooth wave is reversed, it can be distorted in the pin shape at the same time as the upper part.

By using each of the conditions described above in reverse, for example, the horizontal pin-shaped or barrel-shaped distortion (called N / S pin distortion) of the scanning line generated at the upper and lower portions of the screen of the cathode ray tube can be corrected. Can be.

That is, in this apparatus, a pair of coils 5a, 5b attached to the neck portion of the cathode ray tube 4 flows a sawtooth modulated current in a vertical period, changes its amplitude or polarity, and By restoring the raster size changed by the vertical deflection field, the scanning lines can be distorted in the barrel or pin shape at the upper and lower portions of the screen, and the distortion that has occurred originally can be corrected.

In addition, when the distortion is unbalanced in the upper and lower parts, unbalance is achieved by changing the DC level of the sawtooth current flowing through the coils 5a and 5b and thereby reverting the position of the raster moved up and down by the vertical deflection field. The distortion can also be corrected for one distortion.

In this apparatus, the amount of distortion of the scanning lines in the upper and lower portions of the screen is uniquely determined by the vertical deflection device (deflection current value) on the screen of the cathode ray tube. Thus, for example, as described above, by using the waveform obtained by voltage conversion of the vertical deflection current as the original signal, the correction current flowing through the coil at any vertical position on the screen is independent of the raster size, the vertical linearity, the vertical deflection frequency, and the like. And a constant correction amount can always be obtained.

Therefore, in this apparatus, a pair of coils are provided in the neck portion of the cathode ray tube, and the scanning line generated at the upper and lower portions of the screen of the cathode ray tube by moving the trajectory of the electron beam incident on the deflection center by the magnetic field generated by the coil up and down. The pin-shaped or barrel-shaped distortion in the horizontal direction can always be correctly corrected and adjusted.

In this apparatus, the correction current flowing through the coil can always obtain a constant correction amount for the raster size, the vertical linearity, the vertical deflection frequency, and so on. This can also be effectively used for wide televisions and the like whose size changes with respect to the screen mode.

In the above-described apparatus, a control terminal (means) 1a for controlling the amplitude and polarity of the amplifier 1 and a control terminal (means) 2a for controlling the DC level in the amplifier 2 are provided. By doing so, for example, the user can adjust these correction amounts arbitrarily. As a result, correction can be made arbitrarily in accordance with the user's preference.

In the above-described apparatus, the position at which the coils 5a and 5b are provided is not limited to the point where the three electron beams from the electron gun intersect, and is a so-called inline type apparatus in which the three electron beams are arranged horizontally. It may be located at any place along the path from the electron gun to the deflection center. However, the condition is that three electron beams are arranged horizontally in an inline type.

In the above-described apparatus, the coils 5a and 5b are provided in series with respect to the vertical deflection yoke 12 and at the same time, the impedances thereof can be determined to perform the above-described correction. As a result, for example, as long as the distortion of the pin or barrel shape in the horizontal direction of the scanning line is corrected, it is also possible to adjust the correction without adjustment.

In the above-described apparatus, by processing the sawtooth signal of the vertical period supplied to the pair of coils 5a and 5b again non-linearly, for example, vertical middle pin / barrel distortion can be corrected. Done.

In this way, according to the deflecting apparatus described above, a pair of coils are provided in the neck portion of the cathode ray tube, and the trajectory of the electron beam incident on the deflection center is moved up and down by the magnetic field generated by the coils, and the scanning line of the By correcting the distortion, the pin-shaped or barrel-shaped distortion in the horizontal direction of the scanning line generated in the upper and lower portions of the screen of the cathode ray tube can be corrected and adjusted well.

In the above-described embodiment, since the other end of the series circuit of the coils 5a and 5b is grounded, the circuit for the voltage and current conversion requires a circuit of both power sources. For example, the coils 5a, When amplifiers are provided at both ends of the series circuit of 5b) to achieve so-called balanced amplifier mechanisms, driving with a single power supply is also possible.

According to the present invention, a pair of coils are provided in the neck portion of the cathode ray tube, and the scanning line generated in the upper and lower portions of the screen of the cathode ray tube by moving the trajectory of the electron beam incident on the deflection center up and down by the magnetic field generated by the coil. The pin and barrel distortions in the horizontal direction can be corrected and adjusted at all times.

In addition, according to the present invention, the correction current flowing through the coil can always obtain a constant correction amount with respect to raster size, vertical linearity, vertical deflection frequency, etc., thereby changing the horizontal / vertical deflection frequency so-called multi-scan model or vertical raster. This can also be effectively used for wide televisions and the like whose size changes with respect to the screen mode.

1 is a configuration diagram of an example of a deflection apparatus applied to the present invention.

2 is a configuration diagram of an example of the main portion.

3 is a diagram for explaining the operation.

4 is a diagram for explaining the operation.

* Explanation of symbols for main parts of the drawings

1. Amplifier controlling amplitude and polarity 2. Amplifier controlling DC level

2a. Control terminal 3. Amplifier for voltage and current conversion

3a. Control terminal 4. Cathode ray tube

5a, 5b. A pair of coils fitted with necks

6a, 6b. Cores 7a-7d. coil

8. Electron beam 11. Vertical deflection current output circuit

12. Vertical deflection yoke 13. Resistor for current detection

Claims (3)

An amplifier supplied with a sawtooth signal of vertical period, A voltage current converter for converting an output voltage from the amplifier into a current; And a pair of coils provided opposite to the neck portion of the cathode ray tube in a horizontal direction and simultaneously supplying an output current from the voltage-current converter circuit and generating a magnetic field crossing the neck portion, A deflection device, characterized in that for correcting the horizontal curve of the scanning line. The method of claim 1, And a setting means for arbitrarily setting the polarity and amplitude of the sawtooth signal. The method of claim 1, And a second setting means for arbitrarily setting a second amplifier for changing the DC level of the output voltage from the amplifier and a second setting means for arbitrarily setting the DC level.

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